/* Copyright (C) 1989-2004 artofcode LLC. All rights reserved. This software is provided AS-IS with no warranty, either express or implied. This software is distributed under license and may not be copied, modified or distributed except as expressly authorized under the terms of the license contained in the file LICENSE in this distribution. For more information about licensing, please refer to http://www.ghostscript.com/licensing/. For information on commercial licensing, go to http://www.artifex.com/licensing/ or contact Artifex Software, Inc., 101 Lucas Valley Road #110, San Rafael, CA 94903, U.S.A., +1(415)492-9861. */ /* $Id: genarch.c,v 1.11 2004/06/17 21:42:53 giles Exp $ */ /* * Generate a header file (arch.h) with parameters * reflecting the machine architecture and compiler characteristics. */ #include "stdpre.h" #include #include /* * In theory, not all systems provide or , or declare * memset in , but at this point I don't think we care about any * that don't. */ #include #include #include /* We should write the result on stdout, but the original Turbo C 'make' */ /* can't handle output redirection (sigh). */ private void section(FILE * f, const char *str) { fprintf(f, "\n\t /* ---------------- %s ---------------- */\n\n", str); } private clock_t time_clear(char *buf, int bsize, int nreps) { clock_t t = clock(); int i; for (i = 0; i < nreps; ++i) memset(buf, 0, bsize); return clock() - t; } private void define(FILE *f, const char *str) { fprintf(f, "#define %s ", str); } private void define_int(FILE *f, const char *str, int value) { fprintf(f, "#define %s %d\n", str, value); } private void print_ffs(FILE *f, int nbytes) { int i; for (i = 0; i < nbytes; ++i) fprintf(f, "ff"); } private int ilog2(int n) { int i = 0, m = n; while (m > 1) ++i, m = (m + 1) >> 1; return i; } int main(int argc, char *argv[]) { char *fname = argv[1]; long one = 1; struct { char c; short s; } ss; struct { char c; int i; } si; struct { char c; long l; } sl; struct { char c; char *p; } sp; struct { char c; float f; } sf; struct { char c; double d; } sd; /* Some architectures have special alignment requirements for jmpbuf. */ struct { char c; jmp_buf j; } sj; long lm1 = -1; long lr1 = lm1 >> 1, lr2 = lm1 >> 2; unsigned long um1 = ~(unsigned long)0; int im1 = -1; int ir1 = im1 >> 1, ir2 = im1 >> 2; union { long l; char *p; } pl0, pl1; int ars; int lwidth = size_of(long) * 8; union { float f; int i; long l; } f0, f1, fm1; int floats_are_IEEE; FILE *f = fopen(fname, "w"); if (f == NULL) { fprintf(stderr, "genarch.c: can't open %s for writing\n", fname); return exit_FAILED; } fprintf(f, "/* Parameters derived from machine and compiler architecture. */\n"); fprintf(f, "/* This file is generated mechanically by genarch.c. */\n"); /* We have to test the size dynamically here, */ /* because the preprocessor can't evaluate sizeof. */ f0.f = 0.0, f1.f = 1.0, fm1.f = -1.0; floats_are_IEEE = (size_of(float) == size_of(int) ? f0.i == 0 && f1.i == (int)0x3f800000 && fm1.i == (int)0xbf800000 : f0.l == 0 && f1.l == 0x3f800000L && fm1.l == 0xbf800000L); section(f, "Scalar alignments"); #define OFFSET_IN(s, e) (int)((char *)&s.e - (char *)&s) define_int(f, "ARCH_ALIGN_SHORT_MOD", OFFSET_IN(ss, s)); define_int(f, "ARCH_ALIGN_INT_MOD", OFFSET_IN(si, i)); define_int(f, "ARCH_ALIGN_LONG_MOD", OFFSET_IN(sl, l)); define_int(f, "ARCH_ALIGN_PTR_MOD", OFFSET_IN(sp, p)); define_int(f, "ARCH_ALIGN_FLOAT_MOD", OFFSET_IN(sf, f)); define_int(f, "ARCH_ALIGN_DOUBLE_MOD", OFFSET_IN(sd, d)); define_int(f, "ARCH_ALIGN_STRUCT_MOD", OFFSET_IN(sj, j)); #undef OFFSET_IN section(f, "Scalar sizes"); define_int(f, "ARCH_LOG2_SIZEOF_CHAR", ilog2(size_of(char))); define_int(f, "ARCH_LOG2_SIZEOF_SHORT", ilog2(size_of(short))); define_int(f, "ARCH_LOG2_SIZEOF_INT", ilog2(size_of(int))); define_int(f, "ARCH_LOG2_SIZEOF_LONG", ilog2(size_of(long))); #ifdef HAVE_LONG_LONG define_int(f, "ARCH_LOG2_SIZEOF_LONG_LONG", ilog2(size_of(long long))); #endif define_int(f, "ARCH_SIZEOF_PTR", size_of(char *)); define_int(f, "ARCH_SIZEOF_FLOAT", size_of(float)); define_int(f, "ARCH_SIZEOF_DOUBLE", size_of(double)); if (floats_are_IEEE) { define_int(f, "ARCH_FLOAT_MANTISSA_BITS", 24); define_int(f, "ARCH_DOUBLE_MANTISSA_BITS", 53); } else { /* * There isn't any general way to compute the number of mantissa * bits accurately, especially if the machine uses hex rather * than binary exponents. Use conservative values, assuming * the exponent is stored in a 16-bit word of its own. */ define_int(f, "ARCH_FLOAT_MANTISSA_BITS", sizeof(float) * 8 - 17); define_int(f, "ARCH_DOUBLE_MANTISSA_BITS", sizeof(double) * 8 - 17); } section(f, "Unsigned max values"); /* * We can't use fprintf with a numeric value for PRINT_MAX, because * too many compilers produce warnings or do the wrong thing for * complementing or widening unsigned types. */ #define PRINT_MAX(str, typ, tstr, l)\ BEGIN\ define(f, str);\ fprintf(f, "((%s)0x", tstr);\ print_ffs(f, sizeof(typ));\ fprintf(f, "%s + (%s)0)\n", l, tstr);\ END PRINT_MAX("ARCH_MAX_UCHAR", unsigned char, "unsigned char", ""); PRINT_MAX("ARCH_MAX_USHORT", unsigned short, "unsigned short", ""); /* * For uint and ulong, a different approach is required to keep gcc * with -Wtraditional from spewing out pointless warnings. */ define(f, "ARCH_MAX_UINT"); fprintf(f, "((unsigned int)~0 + (unsigned int)0)\n"); define(f, "ARCH_MAX_ULONG"); fprintf(f, "((unsigned long)~0L + (unsigned long)0)\n"); #undef PRINT_MAX section(f, "Cache sizes"); /* * Determine the primary and secondary cache sizes by looking for a * non-linearity in the time required to fill blocks with memset. */ { #define MAX_BLOCK (1 << 22) /* max 4M cache */ #define MAX_NREPS (1 << 10) /* limit the number of reps we try */ static char buf[MAX_BLOCK]; int bsize = 1 << 10; int nreps = 1; clock_t t = 0; clock_t t_eps; /* * Increase the number of repetitions until the time is * long enough to exceed the likely uncertainty. */ while (nreps < MAX_NREPS && (t = time_clear(buf, bsize, nreps)) == 0) nreps <<= 1; t_eps = t; while (nreps < MAX_NREPS && (t = time_clear(buf, bsize, nreps)) < t_eps * 10) nreps <<= 1; /* * Increase the block size until the time jumps non-linearly. */ for (; bsize <= MAX_BLOCK;) { clock_t dt = time_clear(buf, bsize, nreps); if (dt > t + (t >> 1)) { t = dt; break; } bsize <<= 1; nreps >>= 1; if (nreps == 0) nreps = 1, t <<= 1; } define_int(f, "ARCH_CACHE1_SIZE", bsize >> 1); /* * Do the same thing a second time for the secondary cache. */ if (nreps > 1) nreps >>= 1, t >>= 1; for (; bsize <= MAX_BLOCK;) { clock_t dt = time_clear(buf, bsize, nreps); if (dt > t * 1.25) { t = dt; break; } bsize <<= 1; nreps >>= 1; if (nreps == 0) nreps = 1, t <<= 1; } define_int(f, "ARCH_CACHE2_SIZE", bsize >> 1); } section(f, "Miscellaneous"); define_int(f, "ARCH_IS_BIG_ENDIAN", 1 - *(char *)&one); pl0.l = 0; pl1.l = -1; define_int(f, "ARCH_PTRS_ARE_SIGNED", (pl1.p < pl0.p)); define_int(f, "ARCH_FLOATS_ARE_IEEE", (floats_are_IEEE ? 1 : 0)); /* * There are three cases for arithmetic right shift: * always correct, correct except for right-shifting a long by 1 * (a bug in some versions of the Turbo C compiler), and * never correct. */ ars = (lr2 != -1 || ir1 != -1 || ir2 != -1 ? 0 : lr1 != -1 ? 1 : /* Turbo C problem */ 2); define_int(f, "ARCH_ARITH_RSHIFT", ars); /* * Some machines can't handle a variable shift by * the full width of a long. */ define_int(f, "ARCH_CAN_SHIFT_FULL_LONG", um1 >> lwidth == 0); /* * Determine whether dividing a negative integer by a positive one * takes the floor or truncates toward zero. */ define_int(f, "ARCH_DIV_NEG_POS_TRUNCATES", im1 / 2 == 0); /* ---------------- Done. ---------------- */ fclose(f); return exit_OK; }